JP2017075932A - Vector network analyzer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To allow relative phase measurement between a signal generator and a receiver, insensitive to external load conditions.SOLUTION: A vector network analyzer (VNA) 400 can include a control processor 420, and a plurality of receivers 410, 411 and 412 coupled with the control processor 420. The receivers 410, 411 and 412 receive common source reference signals from an LO 417, and a coupler/power divider network 445 distributes each of the plurality of source reference signals to a corresponding one of the receivers 410, 411 and 412.SELECTED DRAWING: Figure 4

Description

  The present invention relates generally to electrical test and measurement devices such as vector network analyzers (VNAs).

  Conventional devices such as tracking generators or vector network analyzers (VNAs) need to measure the reflection and transmission of multiple phase-stable devices under test (DUTs). Single or multiple signal generators or receivers share a common local oscillator (LO) to ensure phase stability. The calibration of the system is performed by using an external reflection standard (for example, SOLT (Short-Open-Load-Thru), TRL (Thru-Reflect-Line), SOLR (Short-Open-Load-Reciprocal)). This is dependent on a consistent phase between the calibration time and the measurement time.

  FIG. 1 is a block diagram illustrating an example 100 of a conventional vector network analyzer (VNA) or tracking generator having multiple receivers 110 and 112 and a shared signal 125 (eg, by control processor 120 to LO 116). . In this example, a common source (LO) LO 116 adds a shared signal 125 as a reference signal to each of a plurality of receivers 110 and 112 and injects it into a radio frequency (RF) bulge 106. As a signal (injection signal) and subsequently to the load 102 via the transmission line 104. The receiver 110 also receives a reflected (REFL) port signal 117a from the RF bridge 160. The receiver 112 also receives a reference (REF) port signal 117b from the RF bridge 160.

  Although two receivers 110 and 112 that measure two signals (eg, bridge reference and reflection port) are shown, to measure multiple signals from more complex multi-channel bridges, couplers, or networks. It should be noted that any number of multiple receivers may be utilized. Multiple receivers can be omitted with a single receiver if the phase stable switch is connected in such a way that the loading of the bridge is not disturbed when the path is switched.

  FIG. 2 is a block diagram illustrating an example 200 of a conventional VNA or tracking generator having a single receiver 210 and a shared signal 225 (eg, by control processor 220 through LO 216). Similar to the VNA or tracking generator 100 shown in FIG. 1, the common source LO 216 provides an injection signal to the radio frequency (RF) bulge 206 in addition to providing the shared signal 225 as a reference signal to the receiver 210. (Injection signal) is then supplied to the load 202 via the transmission line 204. The switching circuit 209 receives a reflected (REFL) port signal 207 a and a reference (REF) port signal 207 b from the RF bridge 206. The switching circuit 209 supplies one of the signals 207a and 207b to the receiver 210. In general, the shared signal may be the bridge's own stimulus signal or an LO generated in a manner that is phase stable in the source.

JP 2003-279609 A JP 2004-198415 A

Explanation of calibration method by SOLT (Short-Open-load-Thru) in “Network Analyzer”, Japan Electric Measuring Instruments Manufacturers Association, technical explanation, especially “1 Measurement Principle” and “4 Calibration”, [online], [2016 Search August 10], Internet <URL: http://tech.jemima.or.jp/70902.html?q=tech/70902.html>

Rather than sharing a common synthesizer structure, it is desirable to use a LO source that is not in phase but stable in frequency, rather than sharing a common synthesizer structure, to reduce cost and simplify hardware Will. A typical VNA has various types of reflective bridges or coupler arrangements on its signal generation port. The reference signal combined from the signal generator is delivered to the receiver, but there is a phase error proportional to the reflection coefficient of arcsin (V _ref / V _norm ), and the phase of the reference signal generator relative to the receiver is This makes it difficult to obtain from this reference port alone, without resorting to the fact that the phase of the common LO system between the receiver and the receiver is in phase.

  Roughly speaking, embodiments of the present invention include vector network analyzers that allow relative phase measurements between a signal generator and a receiver without being affected by external load conditions. To do this, an additional signal path is used. Such an embodiment can effectively enable the receiver and signal generator to utilize a relatively unstable independent local oscillator (LO) for stable measurement of the phase of the network response. This effectively allows a single receiver and signal generator to establish their relative phases, or in embodiments that include multiple receivers and multiple signal generators, Effectively making it possible to establish the relative phase of.

FIG. 1 is a block diagram of an example of a conventional vector network analyzer (VNA) or tracking generator having multiple receivers and shared signals. FIG. 2 is a block diagram of an example of a conventional VNA or tracking generator with a single receiver and shared signal. FIG. 3 is a block diagram illustrating an example of a VNA or tracking generator having a calibration path according to an embodiment of the present invention. FIG. 4 is a block diagram illustrating an example of a VNA or tracking generator having a common signal generator source according to an embodiment of the present invention. FIG. 5 is a block diagram illustrating a first example of a VNA or tracking generator having multiple receivers synchronized by a common reference signal according to an embodiment of the present invention. FIG. 6 is a block diagram illustrating a second example of a VNA or tracking generator having multiple receivers synchronized by a common reference signal according to an embodiment of the present invention. FIG. 7 is a block diagram illustrating an example of a VNA or tracking generator having multiple sources synchronized by a single receiver, in accordance with an embodiment of the present invention.

  An embodiment of the present invention is an electrical test and measurement device such as a vector network analyzer (VNA) having a calibration path. In such an embodiment, there is an independent source in the receiver, which allows for higher stability and accuracy in bridge measurements. Also, a variable static phase offset in either the receive synthesizer or the source synthesizer is detected in the measurement and removed as an error term. Furthermore, the cost can be reduced because a synthesizer incorporated in a single integrated circuit (IC) that covers a wide bandwidth at a low cost can be used.

  FIG. 3 illustrates an embodiment of the present invention having a load 302, a transmission line 304, a radio frequency (RF) bridge 306 that provides a reflected port signal 307a and a reference port signal 307b to a switching circuit 309, and a calibration path. FIG. 3 is a block diagram illustrating a first example 300 of a VNA or tracking generator according to an embodiment. In this example, an independent source signal 325 (eg, by signal generator 321, LO 317 and switch 314) and a receiver source reference signal 326 are random phase offsets in the receive channel, shown in series with the source signal. With a phase shifter 315 providing Each of these source signals is phase locked to a common reference signal, controlled by a common control processor 320, and the phase of the source signal is not known. The receiver 310 is switched to either of the two bridge signals, the source, or the internal termination. Although a single receiver 310 is shown, it should be noted that a similar implementation may be used to synchronize multiple receivers.

  In this example, the signal channel signal generator 321 has a single channel receiver that senses the magnitude and phase of a single reflective bridge / coupler 306 and is utilized, for example, in a 1-port VNA. The signal generator 321 and the receiver 310 may use either continuous wave or modulated output. The receiver (s) may be configured to have independent local oscillators, for example, with independent phases. The phase offset of the source signal in the phase shifter 315 may be obtained by sampling the receiver source reference signal 326 in the “source reference path”. Here, S1 may refer to either a switch or a coupling or power distribution network. In embodiments that utilize a single receiver to sample the signal from a single bridge port or multi-bridge port, the switch is designed to provide a consistent load to the bridge at all switch positions May be. This may be realized using, for example, signal path attenuation, impedance matching, buffer processing by amplification, and a termination switch network.

  FIG. 4 is a block diagram illustrating an example VNA or tracking generator 400 having a common signal generation source (eg, by control processor 420 to LO 417) according to an embodiment of the invention. In this example, multiple receivers 410, 411, and 412 have independent LOs 410a, 411a, and 412a, respectively, and multiple phase offsets are synchronized to a common reference signal. In this regard, multiple source reference signals are distributed by the coupler / power distribution network 445. In another embodiment, instead of the coupler / power distribution network 445, it is implemented with a switch.

  In this example, the receivers 410-412 and the signal generators (Generators) can be phase synchronized by switching to a “source reference” signal, measuring the relative phase, and tuning to the same frequency, respectively. The frequency offset between the source and receiver can be adjusted if these signals are within the processing bandwidth of the receivers 410-412. Note that the receivers 410-412 are typically analog or digital receivers using superheterodyne, homodyne, direct conversion or similar receiver techniques. Single or multiple LO signals may be generated by each receiver. For example, LO1 (410a) may actually be three LO signals (eg, LO1a, LO1b and LO1c for a three-stage superheterodyne converter). The signal generator can be a direct source (direct signal source: e.g. VCO and PLL, direct digital source or direct analog source) or an indirect source (indirect signal source: e.g. One local oscillator and baseband signal, or a plurality of local oscillators and baseband signals), which may be either modulated or continuous wave baseband signals .

  FIG. 5 is a block diagram illustrating a first example 500 of a VNA or tracking generator having multiple receivers synchronized by a common reference signal, according to an embodiment of the invention. In this example, a single control processor 520 can control multiple receivers 510, 511, and 512, each having independent LOs 510a, 511a, and 512a with random phase offsets. N source reference signals are delivered from a single signal generator 517. In the figure, a simplified source is shown, but this source is an indirect source (indirect signal source, eg, one local oscillator and baseband signal, or multiple local oscillators and baseband signals). Or a direct source such as a VCO and PLL, direct digital source or direct analog source (directly) Signal source).

  FIG. 6 is a block diagram illustrating a second example 600 of a VNA or tracking generator having multiple receivers (eg, spectrum analyzers) synchronized by a common reference signal according to an embodiment of the present invention. In this example, the synchronization circuit 601 includes a signal source (Gen1) 617 and a common reference clock 618 (eg, 10 MHz 1... 10 MHz N that synchronizes n external spectrum analyzers 610, 611, and 612). Output signal), 10 MHz or other suitable signal for synchronizing the reference signal generator “Gen1” 617, and signal distribution and switching circuits 610b, 611b and 612b for each RF input of the spectrum analyzer, respectively , N RF inputs. The input of signal 1 to signal n to the control processor 620 may be some USB data signal or any other common data bus such as USB / PXI / VXI.

  FIG. 7 is a block diagram illustrating an example VNA or tracking generator 700 having multiple sources 710a, 711a and 712a synchronized by a single receiver 710, according to an embodiment of the invention. In this example, the SPDT (Single pole, dual throw) switches 710b, 711b and 712b of the channel of the signal generator may be internally terminated when the path is open. The stability of the bridge response during switching may be improved using buffers, amplification, attenuation, or other suitable mechanisms. Signal 1 may be a modulated or continuous wave signal. The source (signal generator) may be a direct source composed of a heterodyne source. The phase offset of each signal generator may be detected relative to others, for example, by a common receiver 710. The signal selector 745 supplies one of the plurality of source reference signals to the receiver 710.

  Although the principles of the present invention have been described and illustrated with reference to the illustrated embodiments, the configuration and details of the illustrated embodiments may be altered or combined into desirable forms without departing from these principles. Can understand. In the above description, the description is focused on a specific embodiment, but other configurations are also conceivable.

  In particular, the expression “according to an embodiment of the present invention” is used in the present application, but such a phrase roughly means that it can be a reference embodiment, and it can be used in the configuration of a specific embodiment. It is not intended to be limiting. As used herein, these terms refer to the same or different embodiments that can be combined in another embodiment.

  Accordingly, the embodiments described in the present application should not be considered as limiting the scope of the present invention in terms of a wide variety of rearrangements, but the detailed description and the accompanying materials are merely for convenience of description. Absent. For example, the concept of the present invention may be described as follows.

Concept 1 of the present invention is a vector network analyzer,
A control processor;
A plurality of receivers coupled to the control processor, the plurality of receivers having a common signal generation source from the control processor;
A coupler / power distribution network configured to distribute each of the plurality of source reference signals to one of the corresponding plurality of the receivers.

  The concept 2 of the present invention is the vector network analyzer of the concept 1, wherein each of the plurality of receivers has an independent local oscillator (LO).

  Concept 3 of the present invention is the vector network analyzer of concept 2 above, wherein at least one independent LO is configured to generate a plurality of LO signals.

  The concept 4 of the present invention is the vector network analyzer of the concept 1, wherein each of the plurality of receivers is one of a group consisting of a superheterodyne receiver, a homodyne receiver, and a direct conversion receiver. It is.

  The concept 5 of the present invention is the vector network analyzer of the concept 1, wherein the common signal generation source is a direct source.

  The concept 6 of the present invention is the vector network analyzer of the concept 5, wherein the direct source is one of a group consisting of a voltage controlled oscillator (VCO) and a phase locked loop (PLL). .

  Concept 7 of the present invention is the vector network analyzer of concept 5, wherein the direct source is one of a group consisting of a direct digital source and a direct analog source.

  The concept 8 of the present invention is the vector network analyzer according to the concept 1, wherein the common signal generation source is an indirect source.

  The concept 9 of the present invention is the vector network analyzer of the concept 8, wherein the indirect source is a group consisting of a single LO using a baseband signal and a plurality of LOs using a baseband signal. One of the

The inventive concept 10 is a vector network analyzer comprising:
A control processor;
A receiver coupled to the control processor;
A switching circuit coupled to the receiver;
A radio frequency (RF) bridge coupled to the switching circuit;
A transmission line coupled to the RF bridge, the transmission line configured to be coupled to a load;
And a signal generator coupled to the RF bridge.

  The concept 11 of the present invention is the vector network analyzer of the concept 10, wherein the RF bridge is configured to supply a plurality of reference signals to the switching circuit.

  Concept 12 of the present invention is the vector network analyzer of concept 10, wherein the signal generator is configured to provide a source signal to the RF bridge.

  Concept 13 of the present invention is the vector network analyzer of concept 10 further comprising a local oscillator (LO) coupled to the receiver.

  Concept 14 of the present invention is the vector network analyzer of concept 10 further comprising a local oscillator (LO) coupled to the signal generator.

  Concept 15 of the present invention is the vector network analyzer of concept 14 further comprising a switch coupled to the signal generator and configured to switch between the RF bridge and the receiver.

  Concept 16 of the present invention is the vector network analyzer of concept 14, wherein the control processor is configured to phase lock the signal generator to a common reference signal.

300 VNA or tracking generator 302 Load 306 RF bridge 307a Reflected port signal (REFL)
307b Reference port signal (REF)
309 Switching circuit 310 Receiver 314 Switch 315 Phase shifter 317 Local oscillator 320 Control processor 321 Signal channel generator 325 Source signal 326 Receiver source reference signal 400 VNA or tracking generator 406-1 RF bridge 1
406-n RF bridge n
410 receiver 411 receiver 412 receiver 410a local oscillator 411a local oscillator 412a local oscillator 410b switch 411b switch 412b switch 415 phase shifter 417 local oscillator 420 control processor 445 coupler / power distribution network 500 VNA or tracking generator 510 receiver 511 receiver 512 receiver 515 Phase shifter 520 Control processor 545 Coupler / power distribution network 600 VNA or tracking generator 610 External spectrum analyzer 611 External spectrum analyzer 612 External spectrum analyzer 610b Switching circuit 611b Switching circuit 612b Switching circuit 620 Control processor 645 Coupler / power distribution Network 700 VN Or tracking generator 710 receiver 710a local oscillator 711a local oscillator 712a local oscillator 710b switching circuit 711b switching circuit 712b switching circuit 720 control processor 745 N input signal selector

Claims (4)

A control processor;
A plurality of receivers coupled to the control processor, the receivers having a common signal generation source controlled by the control processor;
A vector network analyzer comprising: a coupler / power distribution network configured to distribute each of a plurality of source reference signals to one of a corresponding plurality of the receivers.   The vector network analyzer of claim 1, wherein each of said plurality of receivers has an independent local oscillator (LO).   The vector network analyzer of claim 2, wherein the at least one independent LO is configured to generate a plurality of LO signals. A control processor;
A receiver coupled to the control processor;
A switching circuit coupled to the receiver;
A radio frequency (RF) bridge coupled to the switching circuit;
A transmission line coupled to the RF bridge, the transmission line configured to be coupled to a load;
A vector network analyzer comprising: a signal generator coupled to the RF bridge.

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